Display with Heat Radiation

ABSTRACT

This display includes a light source portion, a first heat radiation member for radiating heat generated by the light source portion, a rear housing covering the first heat radiation member in a state in contact with the first heat radiation member, and a cover member covering a rear surface of the rear housing so that the rear surface of the rear housing is partially exposed outward. The first heat radiation member is arranged on a region corresponding to a region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 15/091,879, filed Apr. 6, 2016 which is a continuation of U.S. application Ser. No. 13/649,302, filed Oct. 11, 2012, which claims priority from Japanese Patent Application No. 2011-224559, filed on Oct. 12, 2011, the disclosures of which are expressly incorporated by reference herein.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a display and a television set, and more particularly, it relates to a display and a television set each including a heat radiation member for radiating heat generated by a light source portion.

Description of the Background Art

A display including a heat radiation member for radiating heat generated by a light source portion is known in general, as disclosed in Japanese Patent Laying-Open No. 2008-130413, for example.

The aforementioned Japanese Patent Laying-Open No. 2008-130413 discloses a liquid crystal display including a liquid crystal panel, a light guide arranged at the back of the liquid crystal panel, an LED (light source portion) arranged on a side portion of the light guide, a reflection sheet arranged at the back of the light guide, a back case (heat radiation member) arranged at the back of the LED and the reflection sheet and a heat sink arranged at the back of the back case for functioning as a rear housing. In this liquid crystal display, the back case is arranged to cover the whole of a region where the LED and the reflection sheet are arranged in a state in contact with the LED and the reflection sheet. The heat sink (rear housing) at the back of the back case is arranged to cover the whole of a region where the back case is arranged. In other words, the back case covering the LED and the reflection sheet is arranged on a region substantially equal to that where the heat sink (rear housing) is arranged as viewed from behind in the aforementioned liquid crystal display. The aforementioned liquid crystal display is so formed that the heat sink (rear housing) radiates heat generated by the LED through the back case in a normal use state.

In the liquid crystal display described in the aforementioned Japanese Patent Laying-Open No. 2008-130413, however, the back case (heat radiation member) radiating the heat generated by the LED is arranged on the region substantially equal to that where the heat sink (rear housing) is arranged as viewed from behind, and hence the area of the region where the back case is arranged is disadvantageously increased.

SUMMARY OF THE INVENTION

The present invention has been proposed in order to solve the aforementioned problem, and an object of the present invention is to provide a display and a television set each capable of reducing the area of a region where a heat radiation member is arranged while excellently radiating heat generated by a light source portion.

A display according to a first aspect of the present invention includes a light source portion, a first heat radiation member arranged in a state in contact with the light source portion for radiating heat generated by the light source portion, a rear housing arranged to cover the first heat radiation member in a state in contact with the first heat radiation member so that a rear surface is partially exposed outward and a cover member covering the rear surface of the rear housing so that the rear surface of the rear housing is partially exposed outward, while the first heat radiation member is arranged on a region corresponding to a region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface.

In the display according to the first aspect, as hereinabove described, the first heat radiation member is arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface, whereby heat generated by the light source portion can be excellently radiated from the outwardly exposed region of the rear housing through the first heat radiation member, dissimilarly to a case where the first heat radiation member is arranged on a region corresponding to a region of the rear housing covered with the cover member as viewed from the side of the rear surface. Further, the area of the region where the first heat radiation member is arranged can be reduced dissimilarly to a case where the first heat radiation member is arranged on a region substantially equal to a region where the rear housing is arranged, for example. Thus, the area of the region where the first heat radiation member is arranged can be reduced while excellently radiating the heat generated by the light source portion.

In the aforementioned display according to the first aspect, the light source portion is preferably mounted on the first heat radiation member, and the first heat radiation member mounted with the light source portion is preferably arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface of the rear housing. According to this structure, the distance between the light source portion mounted on the first heat radiation member and the outwardly exposed region of the rear housing can be relatively reduced, whereby the heat generated by the light source portion can be quickly radiated from the outwardly exposed region of the rear housing through the first heat radiation member.

In the aforementioned display according to the first aspect, a surface of the first heat radiation member closer to the rear housing is preferably arranged to be in surface contact with an inner surface of the rear housing. According to this structure, heat radiation can be more effectively performed as compared with a case where the surface of the first heat radiation member closer to the rear housing is arranged to be in point contact or in line contact with the inner surface of the rear housing.

In this case, the first heat radiation member preferably has a first projecting portion protruding toward the inner surface of the rear housing, and a surface of the first projecting portion of the first heat radiation member is preferably arranged to be in surface contact with the inner surface of the rear housing. According to this structure, the first projecting portion can easily and more effectively radiate the heat.

In the aforementioned display including the first heat radiation member having the first projecting portion, both of the surface of the first projecting portion of the first heat radiation member and a portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion are preferably in the form of planar surfaces. According to this structure, the surface of the first projecting portion of the first heat radiation member and the portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion can be easily brought into surface contact with each other.

In the aforementioned display including the first heat radiation member having the first projecting portion, the rear housing is preferably rectangularly formed and so provided that a portion around an outer peripheral portion is exposed outward from the cover member, and a region where the surface of the first projecting portion of the first heat radiation member and the inner surface of the rear housing are in surface contact with each other is preferably arranged in the vicinity of one side constituting the outer peripheral portion of the rectangularly formed rear housing to extend along this side. According to this structure, the region where the surface of the first projecting portion of the first heat radiation member and the inner surface of the rear housing are in surface contact with each other is arranged to extend along one side so that the heat radiation area can be increased, whereby heat radiation can be more effectively performed.

In the aforementioned display in which the surface of the first heat radiation member closer to the rear housing is in surface contact with the inner surface of the rear housing, the first heat radiation member preferably has a second projecting portion protruding toward the inner surface of the rear housing and mounted with a screw member, the rear housing preferably has a recess portion concaved toward the second projecting portion of the first heat radiation member and mounted with the screw member, and a surface of the second projecting portion, mounted with the screw member, of the first heat radiation member and a surface of the recess portion, mounted with the screw member, of the rear housing closer to the first heat radiation member are preferably fixed to each other by the screw member in a state in surface contact with each other. According to this structure, the surface of the second projecting portion of the first heat radiation member and the surface of the recess portion of the rear housing closer to the first heat radiation member can be pressure-welded to each other in the state in surface contact with each other, whereby heat can be rendered more easily conductible, and heat radiation can be more effectively performed.

In this case, both of the surface of the second projecting portion of the first heat radiation member and the surface of the recess portion of the rear housing closer to the first heat radiation member are preferably in the form of planar surfaces. According to this structure, the surface of the second projecting portion of the first heat radiation member and the surface of the recess portion of the rear housing closer to the first heat radiation member can be easily brought into surface contact with each other.

In the aforementioned display including the first heat radiation member having the second projecting portion, the first heat radiation member preferably has a first projecting portion protruding toward the inner surface of the rear housing, a surface of the first projecting portion of the first heat radiation member is preferably arranged to be in surface contact with the inner surface of the rear housing, and a protrusion height of the first projecting portion with respect to a surface of the first heat radiation member is preferably larger than a protrusion height of the second projecting portion with respect to the surface of the first heat radiation member. According to this structure, the surface of the first projecting portion of the first heat radiation member and the portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion come into surface contact with each other on a vertical position higher than that of the second projecting portion, whereby the surface of the first projecting portion of the first heat radiation member and the portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion can be easily brought into surface contact with each other while pressure-welding the surface of the second projecting portion and the surface of the recess portion of the rear housing closer to the first heat radiation member to each other in the surface contact state.

In the aforementioned display according to the first aspect, the light source portion preferably includes a backlight LED source. According to this structure, heat generated by the backlight LED source can be excellently radiated from the outwardly exposed region of the rear housing through the first heat radiation member.

The aforementioned display according to the first aspect preferably further includes a circuit board including a heating element mounted on a portion of the rear surface of the rear housing covered with the cover member, and a second heat radiation member arranged between the circuit board and the rear housing for radiating heat generated by the heating element of the circuit board to the rear housing. According to this structure, the heat generated by the heating element can be easily radiated from the outwardly exposed region of the rear housing through the second heat radiation member also when the circuit board mounted with the heating element is covered with the cover member.

In this case, a third projecting portion protruding toward an inner surface of the cover member is preferably formed on a region of the rear surface of the rear housing corresponding to the heating element of the circuit board while the circuit board is preferably arranged on a surface of the third projecting portion through the second heat radiation member, and the display is preferably so formed that heat generated by the heating element of the circuit board covered with the cover member is indirectly radiated from the outwardly exposed region of the rear housing through the second heat radiation member and the third projecting portion of the rear housing. According to this structure, the thickness of the second heat radiation member can be reduced by the height of the third projecting portion formed on the rear housing while the heat generated by the heating element is indirectly radiated from the outwardly exposed region of the rear housing through the second heat radiation member and the third projecting portion of the rear housing, whereby the heat generated by the heating element can be easily radiated.

In the aforementioned display in which the third projecting portion is formed on the rear surface of the rear housing, a surface of the third projecting portion closer to the circuit board is preferably in the form of a planar surface. According to this structure, the second heat radiation member can be easily fixed by arranging the second heat radiation member in a clearance between the surface of the third projecting portion, provided in the form of a planar surface, closer to the circuit board and the circuit board to be held therebetween.

In the aforementioned display in which the third projecting portion is formed on the rear surface of the rear housing, the rear housing preferably has a board mounting portion protruding toward the circuit board so that the circuit board is fixed thereto, and a protrusion height of the board mounting portion with respect to the rear surface of the rear housing is preferably larger than a protrusion height of the third projecting portion with respect to the rear surface of the rear housing. According to this structure, the circuit board is fixed on a vertical position higher than that of the third projecting portion, whereby the second heat radiation member can be easily arranged in the clearance between the surface of the third projecting portion closer to the circuit board and the circuit board to be held therebetween.

In the aforementioned display according to the first aspect, the first heat radiation member and the rear housing are preferably made of metal. According to this structure, the heat generated by the light source portion or the heating element can be rendered easily conductible, whereby heat radiation efficiency can be improved.

A television set according to a second aspect of the present invention includes a receiving portion capable of receiving television broadcasting, a light source portion, a first heat radiation member arranged in a state in contact with the light source portion for radiating heat generated by the light source portion, a rear housing arranged to cover the first heat radiation member in a state in contact with the first heat radiation member so that a rear surface is partially exposed outward and a cover member covering the rear surface of the rear housing so that the rear surface of the rear housing is partially exposed outward, while the first heat radiation member is arranged on a region corresponding to a region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface.

In the television set according to the second aspect, as hereinabove described, the first heat radiation member is arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface, whereby heat generated by the light source portion can be excellently radiated from the outwardly exposed region of the rear housing through the first heat radiation member, dissimilarly to a case where the first heat radiation member is arranged on a region corresponding to a region of the rear housing covered with the cover member as viewed from the side of the rear surface. Further, the area of the region where the first heat radiation member is arranged can be reduced dissimilarly to a case where the first heat radiation member is arranged on a region substantially equal to a region where the rear housing is arranged, for example. Thus, a television set capable of reducing the area of the region where the first heat radiation member is arranged while excellently radiating the heat generated by the light source portion can be provided.

In the aforementioned television set according to the second aspect, the light source portion is preferably mounted on the first heat radiation member, and the first heat radiation member mounted with the light source portion is preferably arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface of the rear housing. According to this structure, the distance between the light source portion mounted on the first heat radiation member and the outwardly exposed region of the rear housing can be relatively reduced, whereby the heat generated by the light source portion can be quickly radiated from the outwardly exposed region of the rear housing through the first heat radiation member.

In the aforementioned television set according to the second aspect, a surface of the first heat radiation member closer to the rear housing is preferably arranged to be in surface contact with an inner surface of the rear housing. According to this structure, heat radiation can be more effectively performed as compared with a case where the surface of the first heat radiation member closer to the rear housing is arranged to be in point contact or in line contact with the inner surface of the rear housing.

In this case, the first heat radiation member preferably has a first projecting portion protruding toward the inner surface of the rear housing, and a surface of the first projecting portion of the first heat radiation member is preferably arranged to be in surface contact with the inner surface of the rear housing. According to this structure, the first projecting portion can easily and more effectively radiate the heat.

In the aforementioned television set including the first heat radiation member having the first projecting portion, both of the surface of the first projecting portion of the first heat radiation member and a portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion are preferably in the form of planar surfaces. According to this structure, the surface of the first projecting portion of the first heat radiation member and the portion of the inner surface of the rear housing corresponding to the surface of the first projecting portion can be easily brought into surface contact with each other.

The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an overall perspective view of a liquid crystal television set according to an embodiment of the present invention as viewed from front;

FIG. 2 is an overall perspective view of the liquid crystal television set according to the embodiment of the present invention as viewed from behind;

FIG. 3 is a back elevational view (rear elevational view) of the liquid crystal television set according to the embodiment of the present invention;

FIG. 4 is an exploded perspective view of the liquid crystal television set according to the embodiment of the present invention;

FIG. 5 is a block diagram of the liquid crystal television set according to the embodiment of the present invention;

FIG. 6 is a back elevational view (rear elevational view) showing a heat sink, a reflection sheet and a reflection sheet holder of the liquid crystal television set according to the embodiment of the present invention;

FIG. 7 is a perspective sectional view taken along the line 200-200 in FIG. 3;

FIG. 8 is a sectional view taken along the line 200-200 in FIG. 3;

FIG. 9 is a sectional view taken along the line 300-300 in FIG. 3;

FIG. 10 is a back elevational view (rear elevational view) showing a rear housing, mounted with a circuit board, of the liquid crystal television set according to the embodiment of the present invention;

FIG. 11 is a perspective sectional view taken along the line 400-400 in FIG. 3; and

FIG. 12 is a sectional view taken along the line 400-400 in FIG. 3.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

An embodiment of the present invention is now described with reference to the drawings.

The structure of a liquid crystal television set 100 according to the embodiment of the present invention is described with reference to FIGS. 1 to 12. The liquid crystal television set 100 is an example of the “display” or the “television set” in the present invention.

The liquid crystal television set 100 according to the embodiment of the present invention has a rectangular shape, and includes a frame-shaped front housing 1, a liquid crystal cell 2 stored in the front housing 1 and a stand member 3 supporting the overall liquid crystal television set 100, as shown in FIGS. 1 and 2. Both of the front housing 1 and the stand member 3 are made of resin.

A metal rear housing 4 made of sheet metal (SECC: electrolytic zinc-plated steel) is arranged on the side (along arrow Y2) of the rear surface of the front housing 1, as shown in FIGS. 2 and 3. The rear housing 4 has a rectangular shape and is formed to be smaller than the front housing 1 as viewed from behind, as shown in FIG. 3.

A cover member 5 made of resin is mounted on the rear surface of the metal rear housing 4. The cover member 5 has a rectangular shape and is formed to be smaller than the front housing 1 and the rear housing 4 as viewed from behind.

The cover member 5 covers the rear surface of the rear housing 4 so that a portion around an outer peripheral surface of the rear surface (back surface) of the rear housing 4 is exposed in an inverted U-shaped manner as viewed from behind. An outwardly exposed region 401 of the rear housing 4 is formed to function as a heat radiation portion radiating heat generated by an LED source 6 a and a heating element 81 (see FIG. 4) of a circuit board 8.

As shown in FIGS. 3 and 4, a circuit board 7 having a function of supplying power to the overall liquid crystal television set 100 and the circuit board 8 performing signal processing are mounted on a region 402 of the rear surface of the rear housing 4 mounted with the cover member 5, to align with each other at a prescribed interval in a direction X. The heating element 81 such as an IC generating heat in a normal use state is mounted on the circuit board 8.

A thermal pad mounting portion 41 protruding toward the inner surface of the cover member 5 is formed on a region of the rear surface (along arrow Y2) of the rear housing 4 corresponding to the heating element 81 of the circuit board 8. The thermal pad mounting portion 41 is an example of the “third projecting portion” in the present invention. A thermal pad 82 for radiating heat generated by the heating element 81 toward the side of the rear housing 4 is arranged between the thermal pad mounting portion 41 of the rear housing 4 and the heating element 81 of the circuit board 8 to be held therebetween. The thermal pad 82 is an example of the “second heat radiation member” in the present invention. The thermal pad 82 is made of a mixed material of silicone polymer and ceramic or the like.

A reflection sheet holder 9 a made of sheet metal (SECC), another reflection sheet holder 9 b, still another reflection sheet holder 9 c and a heat sink 10 made of sheet metal (SECC) are arranged in front of the rear housing 4 (along arrow Y1). A reflection sheet 11, a light guide 12, a light diffusion sheet 13, a lens sheet 14, a frame-shaped resin frame 15, the liquid crystal cell 2 mounted with a liquid crystal cell driving board 2 a driving the liquid crystal cell 2 and four bezels 16 are arranged in front of the reflection sheet holders 9 a, 9 b and 9 c and the heat sink 10 (along arrow Y1). The heat sink 10 is an example of the “first heat radiation member” in the present invention.

The backlight LED source 6 a constituted of a plurality of LEDs is arranged on a side portion of the light guide 12, as shown in FIGS. 8 and 9. The LED source 6 a generates heat in the normal use state of the liquid crystal television set 100. The LED source 6 a is mounted on a surface of an LED board 6 b along arrow X1. Another surface (opposite to the surface mounted with the LED source 6 a) of the LED board 6 b along arrow X2 is mounted on a surface of the heat sink 10 along arrow X1 through a heat radiation tape (sheet) 6 c. The “light source portion” in the present invention is so constituted as to include the LED source 6 a, the LED board 6 b and the heat radiation tape 6 c.

As shown in FIG. 4, screw receiving holes 10 a for mounting the reflection sheet holders 9 a and 9 b are formed in the heat sink 10. Heat sink mounting threaded holes 91 a and 91 b for mounting the heat sink 10 are formed on left ends of the reflection sheet holders 9 a and 9 b respectively. Screws 30 are mounted on the heat sink mounting threaded holes 91 a and 91 b of the reflection sheet holders 9 a and 9 b through the screw receiving holes 10 a of the heat sink 10 respectively, thereby fixing the heat sink 10 and the reflection sheet holders 9 a and 9 b to each other.

Screw receiving holes 10 b for mounting the corresponding bezels 16 are formed on upper and lower end portions of the heat sink 10 respectively. As shown in FIG. 6, bezel mounting threaded holes 93 a for mounting the corresponding bezel 16 are formed on right and left ends of the reflection sheet holder 9 a respectively, while bezel mounting threaded holes 93 b for mounting the corresponding bezel 16 are formed on right and left ends of the reflection sheet holder 9 b respectively. As shown in FIG. 4, screw receiving holes 16 a for mounting screws 30 are formed in the bezels 16. The screws 30 are mounted on the bezel mounting threaded holes 93 a and 93 b formed on the left ends of the reflection sheet holders 9 a and 9 b respectively through the screw receiving holes 16 a of the bezels 16 and the screw receiving holes 10 b of the heat sink 10, thereby fixing the bezels 16, the heat sink 10 and the reflection sheet holders 9 a and 9 b to each other.

A plurality of board mounting portions 42 for mounting the respective ones of the circuit boards 7 and 8 are formed on the rear surface (bottom surface) of the rear housing 4. The plurality of board mounting portions 42 are formed to protrude toward the cover member 5. The plurality of board mounting portions 42 are provided with board mounting threaded holes 4 a. As shown in FIG. 12, the height (protrusion height with respect to the rear surface of the rear housing 4) H1 of the board mounting portions 42 of the rear housing 4 is larger than the height (protrusion height with respect to the rear surface of the rear housing 4) H2 of the thermal pad mounting portion 41 of the rear housing 4. All of surfaces of the board mounting portions 42 closer to the circuit board 8 (along arrow Y2) and a surface of the thermal pad mounting portion 41 closer to the circuit board 8 are in the form of planar surfaces.

As shown in FIG. 4, a plurality of screw receiving holes 7 a for receiving a plurality of screws 30 are formed on outer edge portions of the circuit board 7. The plurality of screws 30 are mounted on the plurality of board mounting threaded holes 4 a of the rear housing 4 through the screw receiving holes 7 a of the circuit board 7 respectively, thereby fixing the circuit board 7 to the rear housing 4. Similarly, a plurality of screw receiving holes 8 a for receiving a plurality of screws 30 are formed on outer edge portions or the circuit board 8. The plurality of screws 30 are mounted on the plurality of board mounting threaded holes 4 a of the rear housing 4 through the screw receiving holes 8 a of the circuit board 8 respectively, thereby fixing the circuit board 8 to the rear housing 4.

A plurality of screw receiving holes 4 b are formed on the rear surface of the rear housing 4 along outer edge portions. A plurality of screws 30 are mounted on a plurality of rear housing mounting threaded holes 1 a of the front housing 1 through the plurality of screw receiving holes 4 b of the rear housing 4 respectively, thereby fixing the rear housing 4 to the front housing 1.

A plurality of cover member mounting holes 4 c for mounting the cover member 5 are formed on the rear surface of the rear housing 4. A plurality of screw receiving holes 5 a are formed in the cover member 5. A plurality of screws 30 are mounted on the plurality of cover member mounting threaded holes 4 c of the rear housing 4 through the plurality of screw receiving holes 5 a of the cover member 5 respectively, thereby mounting the cover member 5 on the rear housing 4. The screw 30 mounted on the upper left screw receiving hole 5 a of the cover member 5 is mounted on the upper left board mounting threaded hole 4 a of the rear housing 4 through the upper left screw receiving hole 7 a of the circuit board 7 as viewed from behind.

The cover member 5 is mounted on the lower cover member mounting threaded holes 4 c formed on the rear surface of the rear housing 4 with the corresponding screws 30, to hold a speaker mounting member 17 therebetween. Two speakers 18 are mounted on the speaker mounting member 17. The cover member 5 is mounted to cover the circuit boards 7 and 8 and the speaker mounting member 17 mounted with the two speakers 18 from behind.

The signal processing circuit board 8 mounted on the rear housing 4 has a receiving portion (tuner) 19 capable of receiving television broadcasting. In the liquid crystal television set 100, the receiving portion 19 is connected with the liquid crystal cell 2 and the speakers 18 as shown in FIG. 5, and formed to output a picture signal included in television broadcasting signals (the picture signal and a sound signal) received by an antenna 20 to the liquid crystal cell 2 and to output the sound signal to the speakers 18.

As shown in FIGS. 3 and 6, the reflection sheet holders 9 a, 9 b and 9 c are arranged in the vicinity of sides of an outer peripheral portion of the front housing 1 along arrows Z1, Z2 and X1 as viewed from behind respectively. The three reflection sheet holders 9 a, 9 b and 9 c and the heat sink 10 have a function of pressing four sides of the reflection sheet 11 toward the light guide 12. The liquid crystal cell driving board 2 a for driving the liquid crystal cell 2 is mounted on the rear surface of the reflection sheet holder 9 a arranged in the vicinity of the side of the front housing 1 along arrow Z1.

According to this embodiment, the heat sink 10 is arranged in the vicinity of the side of the rectangular front housing 1 (rear housing 4) along arrow X2 to extend along the side in a direction Z (short-side direction of the front housing 1 (rear housing 4)) as viewed from behind, as shown in FIGS. 3 and 6. Further, the heat sink 10 is arranged on a region (region along arrow X2 in the outwardly exposed region 401) corresponding to the region 401 of the rear housing 4 exposed outward from the cover member 5 as viewed from behind.

As shown in FIG. 6, the heat sink 10 includes a first projecting portion 10 c protruding toward the rear housing 4 and two second projecting portions 10 d formed at a prescribed interval in the direction Z to hold the first projecting portion 10 c therebetween.

As shown in FIGS. 7 and 8, an outer surface 101 of the first projecting portion 10 c of the heat sink 10 is in the form of a planar surface. A portion of an inner surface 403 of the rear housing 4 corresponding to the first projecting portion 10 c is also in the form of a planar surface. Thus, the outer surface 101 of the first projecting portion 10 c of the heat sink 10 is arranged to be in surface contact with the inner surface 403 of the rear housing 4. A region (shown by diagonal lines in FIGS. 7 and 10) where the outer surface 101 of the planar first projecting portion 10 c of the heat sink 10 and the inner surface 403 of the rear housing 4 are in surface contact with each other is arranged in the vicinity of the side of the rear housing 4 along arrow X2 to extend in the direction Z (short-side direction of the rear housing 4). Heat generated by the LED source 6 a is radiated from the outwardly exposed region 401 of the rear housing 4 through the heat sink 10 along a heat radiation path A shown in FIG. 8.

As shown in FIGS. 8 and 9, the height (protrusion height with respect to the surface (rear surface) of the heat sink 10) H4 of the first projecting portion 10 c is larger than the height (protrusion height with respect to the surface (rear surface) of the heat sink 10) H3 of the second projecting portions 10 d of the heat sink 10. As shown in FIG. 9, surfaces 102 of the second projecting portions 10 d are in the form of planar surfaces. According to this embodiment, rear housing mounting threaded holes 10 e for mounting the rear housing 4 are formed on the surfaces 102 of the second projecting portions 10 d. Recess portions 4 d concaved toward the second projecting portions 10 d of the heat sink 10 are formed on portions of the rear housing 4 corresponding to the rear housing mounting threaded holes 10 e of the second projecting portions 10 d of the heat sink 10. Screw receiving holes 4 e for mounting screws 30 are formed in the recess portions 4 d of the rear housing 4. The screws 30 are mounted on the rear housing mounting threaded holes 10 e of the second projecting portions 10 d of the heat sink 10 through the screw receiving holes 4 e of the read housing 4, thereby fixing (pressure-welding) surfaces 404 of the recess portions 4 d of the rear housing 4 along arrow Y1 and the surfaces 102 of the second projecting portions 10 d of the heat sink 10 along arrow Y2 to each other in a state in surface contact with each other. Heat generated by the LED source 6 a is radiated from the screws 30 and the outwardly exposed region 401 of the rear housing 4 through the heat sink 10 along a heat radiation path B shown in FIG. 9.

As shown in FIG. 6, screw receiving holes 91 c for mounting the reflection sheet holders 9 a and 9 b are formed in the reflection sheet holder 9 c. Reflection sheet holder mounting threaded holes 92 a and 92 b for mounting the reflection sheet holder 9 c are formed on the right ends of the reflection sheet holders 9 a and 9 b respectively. Screws 30 are mounted on the reflection sheet holder mounting threaded holes 92 a and 92 b of the reflection sheet holders 9 a and 9 b through the screw receiving holes 91 c of the reflection sheet holder 9 c, thereby fixing the reflection sheet holders 9 a and 9 b and the reflection sheet holder 9 c to each other.

As shown in FIGS. 4 and 6, screw receiving holes 92 c for mounting the corresponding bezels 16 are formed on upper and lower end portions of the reflection sheet holder 9 c respectively. Screws 30 are mounted on the bezel mounting threaded holes 93 a and 93 b formed on the right ends of the reflection sheet holders 9 a and 9 b through the screw receiving holes 16 a of the bezels 16 and the screw receiving holes 92 c on the upper and lower end portions of the reflection sheet holder 9 c, thereby fixing the bezels 16 and the reflection sheet holders 9 a, 9 b and 9 c to each other.

As shown in FIG. 10, the heating element 81 mounted on the circuit board 8 is mounted on the region 402 of the rear surface of the rear housing 4 covered with the cover member 5. The thermal pad 82 arranged between the circuit board 8 and the rear housing 4 is arranged to overlap with the heating element 81 of the circuit board 8 as viewed from behind. Further, the thermal pad 82 is formed to be smaller than the heating element 81 as viewed from behind.

As shown in FIGS. 11 and 12, a rear surface (along arrow Y2) 41 a of the thermal pad mounting portion 41 of the rear housing 4 is in the form of a planar surface. Further, the rear surface 41 a of the thermal pad mounting portion 41 of the rear housing 4 is formed to be in surface contact with a front surface (along arrow Y1) 82 a of the thermal pad 82. A rear surface (along arrow Y2) 82 b of the thermal pad 82 is arranged to be in surface contact with a front surface (along arrow Y1) 80 of the circuit board 8. Heat generated by the heating element 81 mounted on the circuit board 8 is radiated from the outwardly exposed region 401 of the rear housing 4 through the thermal pad 82 and the thermal pad mounting portion 41 of the rear housing 4 along a heat radiation path C shown in FIG. 11.

According to this embodiment, as hereinabove described, the heat sink 10 is arranged on the region corresponding to the region 401 of the rear housing 4 exposed outward from the cover member 5 as viewed from behind. Thus, the heat generated by the LED source 6 a can be excellently radiated from the outwardly exposed region 401 of the rear housing 4 through the heat sink 10, dissimilarly to a case where the heat sink 10 is arranged on the region 402 of the rear housing 4 covered with the cover member 5 as viewed from behind. Further, the area of the region where the heat sink 10 is arranged can be reduced dissimilarly to a case where the heat sink 10 is arranged on a region substantially equal to the region where the rear housing 4 is arranged, for example. Consequently, the area of the region where the heat sink 10 is arranged can be reduced while excellently radiating the heat generated by the LED source 6 a.

According to this embodiment, as hereinabove described, the heat sink 10 mounted with the LED source 6 a is arranged on the region corresponding to the region 401 of the rear housing 4 exposed outward from the cover member 5 as viewed from the side of the rear surface of the rear housing 4. Thus, the distance between the LED source 6 a mounted on the heat sink 10 and the outwardly exposed region 401 of the rear housing 4 can be relatively reduced, whereby the heat generated by the LED source 6 a can be quickly radiated from the outwardly exposed region 401 of the rear housing 4 through the heat sink 10.

According to this embodiment, as hereinabove described, the surface 101 of the heat sink 10 closer to the rear housing 4 is arranged to be in surface contact with the inner surface 403 (404) of the rear housing 4. Thus, heat radiation can be more effectively performed as compared with a case where the surface 101 of the heat sink 10 closer to the rear housing 4 is arranged to be in point contact or in line contact with the inner surface 403 (404) of the rear housing 4.

According to this embodiment, as hereinabove described, both of the surface 101 of the first projecting portion 10 c of the heat sink 10 and the portion of the inner surface 403 of the rear housing 4 corresponding to the surface 101 of the first projecting portion 10 c are in the form of planar surfaces. Thus, the surface 101 of the first projecting portion 10 c of the heat sink 10 and the portion of the inner surface 403 of the rear housing 4 corresponding to the surface 101 of the first projecting portion 10 c can be easily brought into surface contact with each other.

According to this embodiment, as hereinabove described, the region where the surface 101 of the first projecting portion 10 c of the heat sink 10 and the inner surface 403 of the rear housing 4 are in surface contact with each other is arranged in the vicinity of one side constituting the outer peripheral portion of the rectangularly formed rear housing 4 to extend along one side so that the region where the surface 101 of the first projecting portion 10 c of the heat sink 10 and the inner surface 403 of the rear housing 4 are in surface contact with each other is arranged to extend along one side and the heat radiation area can be increased, whereby the heat radiation can be more effectively performed.

According to this embodiment, as hereinabove described, the surfaces 102 of the second projecting portions 10 d of the heat sink 10 mounted with the screws 30 and the surfaces 404 of the recess portions 4 d of the rear housing 4 mounted with the screws 30 are fixed to each other with the screws 30 in the surface-contact state so that the surfaces 102 of the second projecting portions 10 d of the heat sink 10 and the surfaces 404 of the recess portions 4 d of the rear housing 4 can be pressure-welded to each other in the surface-contact state, whereby heat can be rendered more easily conductible, and the heat radiation can be more effectively performed as a result.

According to this embodiment, as hereinabove described, all of the surfaces 102 of the second projecting portions 10 d of the heat sink 10 and the surfaces 404 of the recess portions 4 d of the rear housing 4 closer to the heat sink 10 are in the form of planar surfaces. Thus, the surfaces 102 of the second projecting portions 10 d of the heat sink 10 and the surfaces 404 of the recess portions 4 d of the rear housing 4 closer to the heat sink 10 can be easily brought into surface contact with each other.

According to this embodiment, as hereinabove described, the protrusion height H4 of the first projecting portion 10 c with respect to the surface (rear surface) of the heat sink 10 is rendered larger than the projection height H3 of the second projecting portions 10 d with respect to the surface (rear surface) of the heat sink 10. Thus, the surface 101 of the first projecting portion 10 c of the heat sink 10 and the portion of the inner surface 403 of the rear housing 4 corresponding to the surface 101 of the first projecting portion 10 c come into surface contact with each other on the vertical position higher than that of the second projecting portions 10 d, whereby the surface 101 of the first projecting portion 10 c of the heat sink 10 and the portion of the inner surface 403 of the rear housing 4 corresponding to the surface 101 of the first projecting portion 10 c can be easily brought into surface contact with each other while pressure-welding the surfaces 102 of the second projecting portions 10 d of the heat sink 10 and the surfaces 404 of the recess portions 4 d of the rear housing 4 closer to the heat sink 10 to each other in the surface-contact state.

According to this embodiment, as hereinabove described, the backlight LED source 6 a is so provided that the heat generated by the backlight LED source 6 a can be excellently radiated from the outwardly exposed region 401 of the rear housing 4 through the heat sink 10.

According to this embodiment, as hereinabove described, the thermal pad 82 for radiating the heat generated by the heating element 81 of the circuit board 8 to the rear housing 4 is so provided that the heat generated by the heating element 81 can be easily radiated from the outwardly exposed region 401 of the rear housing 4 through the thermal pad 82 also when the circuit board 8 mounted with the heating element 81 is covered with the cover member 5.

According to this embodiment, as hereinabove described, the heat generated by the heating element 81 of the circuit board 8 covered with the cover member 5 is indirectly radiated from the outwardly exposed region 401 of the rear housing 4 through the thermal pad 82 and the thermal pad mounting portion 41 of the rear housing 4 so that the thickness of the thermal pad 82 can be reduced by the height of the thermal pad mounting portion 41 formed on the rear housing 4 and the heat generated by the heating element 81 is indirectly radiated from the outwardly exposed region 401 of the rear housing 4 through the thermal pad 82 and the thermal pad mounting portion 41 of the rear housing 4, whereby the heat generated by the heating element 81 can be easily radiated.

According to this embodiment, as hereinabove described, the surface 41 a of the thermal pad mounting portion 41 closer to the circuit board 8 is in the form of a planar surface. Thus, the thermal pad 82 can be easily fixed by arranging the thermal pad 82 in the clearance between the surface 41 a of the thermal pad mounting portion 41 closer to the circuit board 8 and the circuit board 8 to be held therebetween.

According to this embodiment, as hereinabove described, the protrusion height H1 of the board mounting portions 42 with respect to the rear surface of the rear housing 4 is rendered larger than the protrusion height H2 of the thermal pad mounting portion 41 with respect to the rear surface of the rear housing 4. Thus, the circuit board 8 is fixed on the vertical position higher than that of the thermal pad mounting portion 41, whereby the thermal pad 82 can be easily arranged in the clearance between the surface 41 a of the thermal pad mounting portion 41 closer to the circuit board 8 and the circuit board 8 to be held therebetween.

According to this embodiment, as hereinabove described, the heat sink 10 and the rear housing 4 made of metal are so provided that the heat generated by the LED source 6 a or the heating element 81 can be rendered easily conductible, whereby heat radiation efficiency can be improved.

Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims.

For example, while the present invention is applied to the liquid crystal television set as an example of the display (television set) according to the present invention in the aforementioned embodiment, the present invention is not restricted to this. The present invention is also applicable to another display such as a monitor of a personal computer other than the television set, or a television set other than the liquid crystal television set, for example.

While the heat sink for radiating the heat generated by the light source portion is arranged to extend along the direction Z (short-side direction) of the rear housing in the aforementioned embodiment, the present invention is not restricted to this. The heat sink may alternatively be arranged to extend along the long-side direction of the rear housing, for example, so far as the same is arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from behind.

While the heat sink is arranged to extend along one side of the outer peripheral portion of the rear housing in the aforementioned embodiment, the present invention is not restricted to this. The heat sink may alternatively be arranged to extend along two, three or four sides of the outer peripheral portion of the rear housing, for example, so far as the same is arranged on the region corresponding to the region of the rear housing exposed outward from the cover member as viewed from behind. Also in this case, the area of the region where the heat sink is arranged can be reduced as compared with a case where the heat sink is provided on the overall surface of the rear housing. Further, heat radiation can be more effectively performed as compared with the case where the heat sink is arranged along one side of the outer peripheral portion of the rear housing.

While the heat sink and the rear housing made of sheet metal (SECC) are employed in the aforementioned embodiment, the present invention is not restricted to this. The heat sink or the rear housing may alternatively be made of a material, such as aluminum, for example, other than the sheet metal (SECC), so far as the same can radiate the heat generated by the LED source or the heat element.

While the thermal pad made of the mixed material of silicone polymer and ceramic or the like is employed as an example of the second heat radiation member in the present invention in the aforementioned embodiment, the present invention is not restricted to this. A heat radiation member other than the thermal pad made of the mixed material of silicone polymer and ceramic or the like may alternatively be employed, for example, so far as the same can radiate the heat generated by the LED source or the heat element. 

What is claimed is:
 1. A display apparatus comprising: a display; an optical member; a light source portion positioned near an end portion of said optical member; and a heat radiation member contacting with said light source portion; wherein said heat radiation member includes a first projecting portion contacting with a main surface of said optical member, and a second projecting portion which is separated from said first projecting portion and contacting with said main surface of said optical member, a first distance between said end portion of said optical member and an end portion of a portion of said first projecting portion contacting with said main surface of said optical member that is closer to said end portion of said optical member is shorter than a second distance between said end portion of said optical member and an end portion of a portion of said second projecting portion contacting with said main surface of said optical member that is closer to said end portion of said optical member.
 2. The display apparatus according to claim 1, wherein a length of said portion of said first projecting portion contacting with said main surface of said optical member is shorter than a length of said portion of said second projecting portion contacting with said main surface of said optical member in a direction perpendicular to a longitudinal direction of said light source portion and parallel to said main surface of said optical member.
 3. The display apparatus according to claim 1, wherein said first distance is shorter than said second distance in a direction perpendicular to a longitudinal direction of said light source portion and parallel to said main surface of said optical member.
 4. The display apparatus according to claim 1, wherein each of said first projecting portion and said second projecting portion extends along a direction substantially parallel to a longitudinal direction of said light source portion.
 5. The display apparatus according to claim 1, wherein said first projecting portion and said second projecting portion are positioned in the vicinity of a center of said light source portion.
 6. The display apparatus according to claim 5, wherein said first projecting portion and said second projecting portion extend from a substantially central region of said light source portion to one side direction and other side direction along a longitudinal of said light source portion.
 7. The display apparatus according to claim 1, wherein said first projecting portion and said second projecting portion extend along a longitudinal of said light source portion.
 8. The display apparatus according to claim 1, wherein said heat radiation member curves in the vicinity of peripheral edge of said first projecting portion.
 9. The display apparatus according to claim 1, wherein said heat radiation member curves in the vicinity of peripheral edge of said second projecting portion.
 10. The display apparatus according to claim 1, further comprising a housing, and said heat radiation member includes an extending portion contacting with said housing, a length of a portion of said extending portion contacting with said housing is longer than said first distance in a direction perpendicular to a longitudinal direction of said light source portion and parallel to said main surface of said optical member.
 11. The display apparatus according to claim 10, wherein said extending portion is positioned at substantially center in said longitudinal direction of said light source portion.
 12. The display apparatus according to claim 11, wherein said extending portion extends along a direction substantially parallel to said longitudinal direction of said light source portion.
 13. The display apparatus according to claim 10, wherein said heat radiation member includes a recess portion arranged between said extending portion and said main surface of said optical member.
 14. The display apparatus according to claim 13, wherein said recess portion has a shape tapered toward said housing.
 15. The display apparatus according to claim 1, wherein said heat radiation member includes a wall portion positioned near said end portion of said optical member and contacting with said light source portion.
 16. The display apparatus according to claim 15, wherein a surface of said wall portion contacting with said light source portion is arranged substantially perpendicular to said main surface of said optical member.
 17. The display apparatus according to claim 16, wherein said heat radiation member includes a bottom portion contacting with said light source portion and intersecting with said wall portion, a height of said first projecting portion with respect to a surface of said bottom portion contacting with said light source portion is lower than a height of said wall portion with respect to said surface of said bottom portion in a direction perpendicular to a main surface of said display.
 18. The display apparatus according to claim 1, further comprising a housing, and said heat radiation member includes an extending portion contacting with said housing, a length of a portion of said extending portion contacting with said housing is shorter than said second distance in a direction perpendicular to a longitudinal direction of said light source portion and parallel to said main surface of said optical member. 